JP2012134982A - Communications methods and apparatus using physical attachment point identifiers which support dual communications links - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide methods and apparatus for routing messages between an end node and an access node via another access node.SOLUTION: Physical layer identification information is used when identifying a remote, e.g., adjacent, access node as a message destination. Thus, when a connection identifier based on one or more physical layer identifiers is available to a wireless terminal, e.g., from one or more downlink signals received from a destination access node, the wireless terminal can use the connection identifier corresponding to the destination node to route a message via an access node having an established uplink connection. Such connection identifier information can be used even when other addressing information, e.g., network layer address information, associated with the destination access node, may not be available to the wireless terminal.

Description

  The present invention relates to communication systems, and more particularly to a method and apparatus for routing messages based on physical layer information in a wireless communication network such as, for example, cellular.

  The Open System Interconnection (OSI) reference model is useful for describing various communication and routing operations. The OSI reference model includes seven layers with an application layer being the top layer and a physical layer being the bottom layer. The physical layer is the layer that handles the actual physical connections in the system and the attributes of such physical connections. There is a data link layer on the physical layer, often referred to as the link layer. The link layer (layer 2 in the OSI model) is often described as a technology specific transport layer. A network layer (OSI layer 3) exists on the link layer, and here network routing and relay are supported. The network layer is sometimes referred to as the packet layer. For example, it is at the network layer that message / packet routing through the network is performed in one or more paths. Different addressing may also be used to detect messages and signals at different levels. For example, at the network layer level, a network address such as an IP address may be used to route messages / packets. MAC addresses can be used to control message routing at the data link layer level. At the physical level, which is the lowest level of the OSI model, one or more physical identifiers have a relationship to actual physical attributes or characteristics of the source device or destination device. Understanding the different communication layers and the different addressing techniques used for each of these layers will facilitate understanding of the present invention.

  Often communication systems include a plurality of network nodes coupled to an access node to which an end node, such as a mobile device, is connected to the network. Network nodes can be organized in a hierarchy. An end node generally communicates directly with the access node via a connection established with the access node. Such a system supports two-way communication between the end node and the access node, depending on the presence of a bi-directional communication link between the access node and the end node. In such a system, the end node usually does not know the network layer address of the target destination address node, but it is generally not used in such a system for message routing. In particular, it should be noted that information including a physical layer identifier that can be received via a broadcast channel can be known. This approach results in handoff delay and packet loss if the end node only has one bi-directional communication link at a time.

  An end node has a current uplink communication link even if an end node that does not have a current uplink communication link for the target access node does not know the network address of the target access node It should be appreciated that there is a need for a method and apparatus that enables communication with a target access node via an access node.

  In some systems, an end node can simultaneously maintain many two-way communication links with different access nodes. However, such systems generally send messages that are directed to a particular access node to which the end node has a connection, and link that the end node is directly connected to that particular access node. Request to be sent through. In some cases, this approach is inefficient. This is because links, particularly wireless links, tend to vary in terms of quality (eg, characteristics such as delay and loss). As a result, the link to the target destination access may not be the best link available to the end node if a message needs to be sent to this target destination access. In general, this limitation is overcome by relying on network layer communication routed through many hops by using network layer addresses (eg, IP addresses). This approach using network layer addresses is also inefficient, especially when messaging has to deal with link layer specific functions. This is because in some systems, network layer messages tend to be much larger than link layer messages. Such inefficient signaling is not suitable for communication over resource-limited air links.

  It should be understood that there is also a need for a method that allows an end node to send a message over any available wireless communication link independent of the access node to which the message is sent. is there. In at least some embodiments, such messages are inefficient, such as communications involving the use of network layer addresses, such as IP layer addresses, to route information to the destination access node. It would be desirable to be sent without having to rely on typical network layer communications.

  The present invention relates to a method and apparatus for routing messages between an end node and an access node via other access nodes. The method and apparatus of the present invention supports the use of physical layer identification information when identifying remote access nodes, such as adjacent ones, as message destinations. Thus, for example, if a connection identifier based on one or more physical layer identifiers is available to a wireless terminal from one or more downlink signals received from a destination access node, the wireless terminal The connection identifier corresponding to the destination node can be used to route messages via access nodes that have established uplink connections between them. Such connection identifier information can be used even when other addressing information associated with the destination access node is not available to the wireless terminal, eg, network layer address information. .

  Various novel features are directed to an end node method that receives broadcast information from an access node and determines a physical connection point identifier, such as a connection identifier corresponding to the access node, for example. Other features are directed to sending a signal to one access node that includes a connection identifier corresponding to another access node. The connection identifier is based on one or more information units that provide information related to the physical layer connection point. Therefore, according to the present invention, physical layer information can be used as a connection identifier.

  According to the present invention, the access node stores information that maps a connection identifier based on physical layer identification information to one or more higher level addresses. The mapping information is stored in the access node. An access node may, for example, have a connection identifier corresponding to a physical layer attachment point that is local to the access node, in addition to a connection identifier corresponding to a physical layer attachment point of another access node, such as adjacent. Contains mapping information. This is because messages between physically adjacent base stations are routed to neighboring access nodes via existing connections with the access node that is currently a wireless terminal. When sending, it allows the wireless terminal to be based on the physical layer connection identifier without having to send a link layer address or network layer address over the air.

  Various features of the present invention receive a signal from an access node that represents an identifier for an access node address resolution failure and notify the end node of a neighbor notification message for establishing a new access node neighbor. To the end node method.

  Some features are directed to the wireless terminal method and apparatus as well as the novel message of the present invention stored in the wireless terminal, while other features are directed to the new access node method and apparatus. Has also been led. The present invention is also directed to a data storage device, such as a memory device, that stores one or more of the inventive novel messages.

  Although various embodiments have been described in the summary above, not all embodiments need to include the same features, and any of these features may not necessarily be desirable in some embodiments. It will be recognized. Many additional features, embodiments, and advantages of the present invention are described in the detailed description that follows.

FIG. 1 illustrates a typical communication system network implemented in accordance with the present invention. FIG. 2 illustrates a typical end node implemented in accordance with the present invention. FIG. 3 illustrates a general access node implemented in accordance with the present invention. FIG. 4 illustrates a general connection identifier implemented in accordance with the present invention. FIG. 5 illustrates a generic message using the connection identifier of FIG. 4 implemented in accordance with the present invention. FIG. 6 illustrates general signaling performed in accordance with the present invention when an end node maintains a bidirectional connection to one access node and wishes to communicate with another access node. FIG. 7 illustrates the general signaling performed in accordance with the present invention when the end node maintains a bidirectional connection with many connected nodes. FIG. 8 illustrates general signaling performed in accordance with the present invention when an end node initiates a neighbor discovery process between two access nodes. FIG. 9 illustrates a generic PID vs. high level address resolution table used for mapping between PIDs and corresponding high level addresses.

  The method and apparatus according to the present invention is based on physical layer information, such as a physical layer identifier, which can be used to support a communication session with one or more end nodes, such as mobile devices, by way of example. To route. The method and apparatus of the present invention can be used with a wide range of communication systems. For example, the present invention can be used with systems that support mobile communication devices such as notebook computers equipped with modems, PDAs, or various other devices that support wireless interfaces for device movement. .

  FIG. 1 illustrates an exemplary communication system 100, such as a cellular communication network, comprising a plurality of nodes interconnected by communication links and implemented in accordance with the present invention. Exemplary communication system 100 is, for example, a multiple access spread spectrum orthogonal frequency division multiplexing (OFDM) wireless communication system. Nodes in this exemplary communication system 100 exchange information using signals, such as messages, based on a communication protocol, such as the Internet Protocol (IP). The communication link of the system 100 may be implemented using, for example, wired, fiber optic cable, and / or wireless communication technology. The exemplary communication system 100 includes a plurality of end nodes 144, 146, 144 ', 146', 144 ", 146". These access the communication system via a plurality of access nodes 140, 140 ′, 140 ″. The end nodes 144, 146, 144 ′, 146 ′, 144 ″, 146 ″ may be, for example, wireless communication devices or The access nodes 140, 140 ′, and 140 ″ are terminals, for example, base stations. The base station can be realized as a radio access router. The exemplary communication system 100 further includes a number of other nodes 104, 106, 110, 112 that are used to provide interoperability or to provide specific services or functions. In particular, the exemplary communication system 100 includes a server 104 that is used to support state transfer and storage for end nodes. Server node 104 may be, for example, an AAA server. Alternatively, it can be a context transfer server. Alternatively, it may be a server including both an AAA server function and a context transfer server function.

  A typical system 100 as shown in FIG. 1 shows a network 102 that includes a server 104 and a node 106 connected to intermediate network nodes 110 by corresponding network links 105 and 107, respectively. The intermediate network node 110 in the network 102 also provides interconnectivity to network nodes external to the network 102 via the network link 111. Network link 111 is also connected to another intermediate network node 112 that provides connectivity to multiple access nodes 140, 140 ', 140 "via network links 141, 141', 141", respectively. It is connected.

  Each access node 140, 140 ′, 140 ″ has a plurality of N ends via a corresponding access link (145, 147), (145 ′, 147 ′), (145 ″, 147 ″), respectively. It is shown to provide connections for nodes (144, 146), (144 ', 146'), (144 ", 146"). In the general communication system 100, each access node 140, 140 ' , 140 "is shown as using a radio technology, such as a radio access link, to provide access. For example, radio coverage areas such as communication cells 148, 148 ', 148 "of access nodes 140, 140', 140", respectively, are illustrated as circles surrounding the corresponding access nodes.

  The general communication system 100 is used as a basis for the description of various embodiments of the present invention, as will be described. In an alternative embodiment of the invention, the number and type of network nodes, the number and types of access nodes, the number and types of end nodes, the number and types of servers and other agents, the number and types of links, And the inter-node connectivity includes various network topologies that can differ from that of the exemplary communication system 100 shown in FIG.

  In various embodiments of the present invention, some of the functional entities shown in FIG. 1 may be omitted or combined. The location or arrangement of these functional entities in the network can also vary.

  FIG. 2 is a detailed description of a generic end node 200 that is a wireless terminal such as a mobile node implemented in accordance with the present invention. The general end node 200 shown in FIG. 2 is a device that can be used as any one of the end nodes 144, 146, 144 ′, 146 ′, 144 ″, 146 ″ shown in FIG. It shows in detail. In the embodiment of FIG. 2, end node 200 includes a processor 204, a wireless communication interface 230, a user input / output interface 240, and a memory 210 connected together by a bus 206. Accordingly, various components of end node 200 can exchange information, signals, and data via bus 206. The components 204, 206, 210, 230, 240 of the end node 200 are arranged inside the housing 202.

  The wireless communication interface 230 provides a mechanism by which internal components of the end node 200 can send and receive signals to and from network nodes such as access nodes and external devices. The wireless communication interface 230 is used, for example, to couple the receiver module 232 with a corresponding receive antenna 236 and the end node 200 to other network nodes such as a wireless communication channel. And a transmitter module 234 with a transmit antenna 238. In some embodiments, the transmitter module 234 includes an orthogonal frequency division multiplexing (OFDM) transmitter.

  The typical end node 200 also includes a user input device 242 such as a keypad and a user output device 244 such as a display. These are connected to the bus 206 via the input / output interface 240. Accordingly, user input / output devices 242, 244 can exchange information, signals, and data with other components of end node 200 via user input / output interface 240 and bus 206. Devices 242 and 244 associated with user input / output interface 240 provide a mechanism by which a user can manipulate end node 200 to perform various tasks. In particular, user input device 242 and user output device 244 control applications such as modules, programs, routines, and / or functions that a user executes on end node 200 or memory 210 of end node 200. Provide a function that makes it possible.

  A processor 204 controlled by various modules such as routines included in the memory 210 controls the operation of the end node 200 to perform various signaling and processing as described below. The modules included in the memory 210 are executed at startup or in response to a call by another module. At run time, modules can exchange data, information, and signals. At run time, the modules can further share data and information. In the embodiment of FIG. 2, the memory 210 of the end node 200 of the present invention includes a signaling / control module 212 and signaling / control data 214.

  The signaling / control module 212 controls processing related to transmission and reception of signals, such as messages, in order to manage state information storage, retrieval, or processing. Signaling / control data 214 includes state information such as, for example, parameters, states, and / or other information regarding the operation of the end node. In particular, the signaling / control data 214 includes configuration information 216 such as end node identification information and operational information 218 such as information regarding current processing status, status of unresolved responses, and the like. The module 212 performs access to the data 214 and / or modifications such as updating the setting information 216 and the operation information 218, for example.

  Message generation module 251 generates messages for various operations of end node 200. Neighbor notification message 280 and signaling message 281 are exemplary messages generated in accordance with the present invention.

  The link selection module 213 may use a plurality of links available to the end node 200 for transmission of the next message ready for transmission by the end node 200, for example, a link such as the best link. Select. Such a link selection algorithm may include various link quality parameters, including but not limited to at least some of link latency requirements, link channel condition requirements, link error rate requirements, and link transmit power. Based.

  The physical layer connection point identifier (PID) determination module 270 determines a PID corresponding to the broadcast signal received from the access node. The PID determination module 270 includes a cell identification module 271, a carrier identification module 272, and a sector identification module 273. In some, but not all, combinations of cell identifiers, carrier identifiers, and sector identifiers are used as physical attachment point identifiers. Each of these identifier elements corresponds to physical layer identification information. For example, the cell identifier identifies a physical cell or cell type. The carrier identifier identifies a physical carrier, such as a carrier frequency or tone block, for example, while the sector identifier identifies a sector in the corresponding cell. Not all of this information is required to implement a PID, and the specific elements of the PID can vary depending on the system implementation. For example, in a system that does not use sectorized cells, there may be no need for a sector ID. Similarly, in a single carrier system, there will be no need for a carrier ID. In one exemplary system, performing PID determination includes operating a cell identification module 271 for cell identifier determination, operating a carrier identification module 272 for carrier identifier determination, Each step comprising operating the sector identifier module 273 for determination of the identifier. Thus, different signals passing through a single physical transmission element, such as an antenna, correspond to different physical layer attachment points, for example, each of the different physical layer attachment points is at least local by a combination of physical identifiers. It should be recognized that unique areas are uniquely identified. For example, a combination of an antenna identifier or sector identifier combined with a first carrier identifier is used to identify a first physical layer attachment point, while a second combined with the same antenna identifier or sector identifier. It should be appreciated that the carrier identifier can be used to identify the second physical layer attachment point.

  The physical layer connection point identifier (PID) information 260 is a list of PIDs (PID1 261, PID2 262) determined using the PID determination module 260. One common example of a physical layer connection point identifier (PID) may be a connection identifier (CID) included in the message when the message is transmitted and / or received. . Hereinafter, a general CID will be described.

  The memory 210 also includes a neighbor notification module 290, a message transmission control module 292, and a link establishment module 294. The neighbor notification module 290 is used to send a neighbor notification, such as a neighbor notification message 280, to the access node, for example. Message transmission control module 292 is used to control transmitter module 234. The link establishment module 294 is used to establish a wireless communication link with the access node.

  FIG. 3 provides a detailed example of a general access node 300 implemented in accordance with the present invention. The general access node 300 as shown in Fig. 3 details the device that can be used as any one of the access nodes 140, 140 ', 140 "shown in Fig. 1. In this embodiment, the access node 300 includes a processor 304, a memory 310, a network / internetwork interface 320, and a wireless communication interface 330 connected together by a bus 306. Components can exchange information, signals, and data via bus 306. Components 304, 306, 310, 320, 330 of access node 300 are located within housing 302. .

  Network / internetwork interface 320 provides a mechanism by which internal components of access node 300 can send and receive signals to and from external devices and network nodes. The network / internetwork interface 320 includes a receiver module 322 and a transmitter module 324 that are used to connect the node 300 to other network nodes via copper or fiber optic lines. The wireless communication interface 330 also provides a mechanism by which internal components of the access node 300 can send and receive signals between a network node, such as an end node, and an external device. The wireless communication interface 330 includes, for example, a receiver module 332 with a corresponding receiving antenna 336 and a transmitter module 334 with a corresponding transmitting antenna 338. Interface 330 is used to couple access node 300 to other network nodes, such as wireless communication channels.

  The processor 304 controls the operation of the access node 300 under the control of various modules, such as routines contained in the memory 310, for various signaling and processing. Each module included in the memory 310 is executed at startup or when called by another module that can exist in the memory 310. At run time, modules can exchange data, information, and signals. At run time, the modules may further share data and information.

  In the embodiment of FIG. 3, the memory 310 of the access node 300 of the present invention includes a signal generation module 314 for signal generation, a packet routing module 350 for routing signals and messages, and a network layer address. It includes a mapping module 312 that maps PIDs and an address resolution table 311 that contains PIDs for IP address mappings 317. The memory 310 further includes an end node identification module 351 that identifies the end node with which the access node 300 is communicating, an uplink resource assigned to the end node, and a resource 341 assigned to the end node X. It also includes uplink resource allocation information 340 including downlink resource allocation information 345 including resources 346 allocated to end nodes X and allocated to end nodes.

  Although briefly described with reference to FIG. 9, FIG. 9 illustrates an address resolution table 311 ′ that can be used as the address resolution table 311 shown in FIG. 3. The address resolution table 311 ′ includes information indicating PIDs 902, 904, 906, 908, 910, 912 and corresponding IP addresses 903, 905, 907, 909, 911, 913, respectively. Each PID is locally unique. For example, the PIDs of cells that are just adjacent to each other are unique to each other. Note that the contents of the PID may vary depending on the physical characteristics of the access node and the number of physical layer attachment points supported by the access node to which the PID corresponds. In the example of FIG. 9, PIDs 902 and 904 correspond to a first access node (AN1) that supports two sectors using the same carrier. Therefore, in the case of AN1, it is sufficient that the PID includes a cell identifier and a sector type identifier to uniquely identify the physical layer connection point in the cell. PIDs 906, 908, and 910 correspond to cells that support multiple carriers and multiple sectors. Thus, the PID of access node 2 is implemented as a CID, similar to that used in various exemplary embodiments as further described herein. PID 912 corresponds to a third access node that includes a single sector and uses a single carrier. Thus, for example, additional physical layer identification information such as a sector identifier and / or a carrier identifier, but it is sufficient that the PID 6 corresponding to the third access node includes only the cell identifier. Inclusion of such additional information is desirable from a processing point of view when a consistent PID format across many cells is desired.

  FIG. 4 illustrates a generic connection identifier (CID) 400 implemented in accordance with the present invention. The CID 400 includes a slope 410 that is a cell identifier, a sector 420 that is a sector identifier, and a carrier 430 that is a carrier frequency identifier also known as a tone block identifier.

  In a typical communication system using OFDM technology, at the physical layer, the spectrum is divided into many tones and reused in cells and sectors in neighboring geographic areas. To improve the interference characteristics, the tones used at each cell / sector hop over time and the different cells and sectors in the neighboring geographic area are different from each other to specify how the tone hops. Use a hopping sequence. This hopping sequence is generated using a predetermined function controlled by two input variables: a cell identifier such as a slope value and a sector identifier. The sector identifier is implemented as a sector type identifier that indicates which of a plurality of possible sector types a particular sector corresponds to. In one embodiment, the slope value is an integer from 1 to 112, and the sector identification value is an integer from 0 to 5. Neighbor cells and sectors use different pairs of slopes and sector identifiers so that the generated hopping sequences are different. In one embodiment, all sectors in a cell use the same slope value but different sector identifiers, eg, physically adjacent neighbor cells use different slope values.

  A typical OFDM communication system further uses a number of carriers or tone blocks in some embodiments, which groups the available tones into a number of tone blocks. The tones within the tone block are preferably adjacent. In one exemplary system, tone hopping in a given tone block is limited to that tone block. That is, a hopping sequence allows a tone to hop within a tone block, but cannot hop across multiple tone blocks. The tone block is indexed using a carrier identifier. In one embodiment, the carrier identifier is an integer 0, 1, or 2.

When an end node sets up a connection to get wireless networking services,
The network side entity is an access node, eg, a base station in a cell / sector, and the connection is defined in terms of a single tone block. Therefore, in the general OFDM communication system as described above, the combination of the slope, sector identifier, and carrier identifier can be used as a locally unique identifier that identifies the connection of the wireless terminal. Accordingly, this combination is a connection identifier based on one or more physical layer identifiers. In one embodiment, many wireless terminals can have connections to the same base station cell / sector on the same tone block. These connections will typically share the same connection identifier. This is because these connections are connected to the same physical layer attachment point defined by a combination of cells, sectors, and tone blocks. The combination of connection identifier and wireless terminal identifier can be used to indicate a communication connection with a particular wireless terminal.

  The connection identifier is generally a number or combination thereof that uniquely and uniquely identifies the connection. In various embodiments, the number is a physical layer characteristic parameter. For example, in other embodiments, such as the general embodiment of a CDMA communication system, the connection identifier may be a pseudo noise (PN) sequence offset and, for example, a carrier identifier if multiple carriers are used. It can be a combination with other parameters.

  FIG. 5 illustrates a generic message 500 according to the present invention using the connection identifier of FIG. The generic message 500 is a link layer message that includes a CID destination / source address. The CID destination / source address is an optional field in the link layer message according to some embodiments of the present invention. Link layer message 500 includes a link layer control (LLC) type field 510 that identifies the type of message body 530 included in message 500. The CID 520 is a connection ID in the format of the connection ID 400 in FIG. In one embodiment of the present invention, the ClD field 520 identifies a destination physical attachment point when sent from an end node to an access node according to the present invention and is sent from the access node to the end node according to the present invention. If so, identify the source physical connection point.

  FIG. 6 illustrates a general communication method and corresponding signaling performed in accordance with various general embodiments of the present invention. In FIG. 6, end node 630 has no radio uplink link between end node 630 and access node 620, and the end node does not need to know the IP address of access node 620, Communicate with access node 620 via access node 610. The signaling is illustrated with respect to the exemplary system 100 illustrated in FIG. The access nodes 610, 620 are similar to the access nodes 140, 140 ′, 140 ″ of the system 100 of FIG. 1 and are implemented in accordance with the access node 300 of FIG. Is similar to the end nodes 144, 146, 144 ', 146', 144 ", 146" of the system and is implemented according to the end node 200 of FIG.

  In FIG. 6, end node 630 maintains a bi-directional link with access node 610, which indicates that end node 630 can send and receive messages to and from access node 610. means. The end node 630 in FIG. 6 is within the transmission range of the access node 620 but does not have an uplink with the access node 620. This allows the end node 630 to receive and process broadcast information sent by the access node 620 (eg, the broadcast message 640), but the end node 630 can access the access node via the air. The message cannot be sent to 620, meaning that the access node 620 cannot receive or process the message sent by the end node 630 via the air interface. In one embodiment of the invention, this can happen. This is because the end node 630 and the access node 620 do not have sufficient timing synchronization. For example, due to certain restrictions, such as restricted hardware capabilities, the end node 630 currently has a bi-directional connection with the access node 610, but the uplink connection with the access node 620. May not be able to establish. In one embodiment, the uplinks used by access node 610 and access node 620 are on different carriers. For example, the uplink frequency band used by access node 610 is different from the uplink frequency band used by access node 620. For example, if end node 630 has only one radio frequency (RF) chain due to cost considerations, end node 630 can only generate an uplink signal within one band at a given time. The end node 630 cannot simultaneously maintain two uplink connections in two separate frequency bands. In another embodiment, if the uplinks used by access nodes 610, 620 are in the same band, the two uplinks may not be time synchronized. This is because the two access nodes are not time synchronized or because of the difference in propagation delay of signals from the end node 630 to the access nodes 610 and 620. For example, end node 630 has only a single digital processing chain that is limited to one timing synchronization scheme at a time, and end node 630 can only have one according to one timing synchronization scheme at a time. If only the uplink signal can be generated, the end node 630 cannot simultaneously hold the two uplink connections if the two uplink connections are not fully time synchronized with each other.

  End node 630 receives broadcast signal 640 sent by access node 620. Signal 640 according to an embodiment of the present invention can sufficiently determine a connection ID similar to CID 400 of FIG. 4 that corresponds to the specific physical connection of access node 620 transmitting broadcast signal 640. The signal or signal 640 can include a beacon signal and / or a pilot signal that can be transmitted over one or more symbol transmission periods.

  End node 630 sends message 650 to access node 610. In the general embodiment of the present invention, message 650 is the same as or similar to general message 500 of FIG. The CID field of message 650 that is identical to CID 520 in FIG. 5 is set to a connection identifier that identifies the physical connection point of access node 620 that broadcasts signal 640. Thus, this message 650 is directed to the access node 620 even though it has been sent to the access node 610. Note that an end node 630, for example as shown in FIG. 6, does not have an uplink with access node 620 and therefore cannot send message 650 directly to access node 620.

  The access node 610 receives the message 650, checks the CID field of the message 650 corresponding to the CID 520 of FIG. 5, and determines one of its physical connection points from the CID stored in the link layer identification information. Recognize that they are not identified. In such cases, the access node 610 searches the memory for the CID of the message 650 to obtain a mapping for the corresponding higher layer identifier (eg, IP address) of the access node 620.

  For example, a base station containing many sectors operating under a single link layer controller and / or many carriers used under a single link layer controller may be a single There may be many CIDs corresponding to the link layer identifier corresponding to the link layer controller. In embodiments where a separate link layer controller is used for each sector and / or carrier, a different link layer identifier may be used for each different sector and / or carrier. In some embodiments, there is a one-to-one mapping between the physical attachment point and the link layer. However, this is not necessary and there may be several physical attachment points that operate below a single link layer. Thus, many physical layer identifiers may match the same link layer link identifier, but each physical layer identifier connection identifier usually maps to a single link layer link identifier at best.

  Assuming that a mapping to a higher layer address has been found, the access node 610 enters at least the message 650 into a network layer message 660 that includes the destination address set to the identifier of the access node 620. Encapsulate a portion and send this message 660 to the access node 620. In accordance with the present invention, message 660 further includes an end node 630 identifier. This identifier is one of an end node 630 IP address, an end node 630 network access identifier (NAI), and a temporary identifier, depending on the embodiment. Access node 620 receives this message 660 and extracts the encapsulated portion of message 650 from this message 660. Access node 620 examines the CID field of the encapsulated and extracted portion of message 650 and recognizes that this CID field identifies one of its physical attachment points.

  Access node 620 sends a message 670 received by access node 620 that is encapsulated in message 660 and includes at least a portion of message 650. This message 670 also includes an end node 630 identifier similar to that included in message 660. Access node 610 then receives message 670 and determines that this message 670 encapsulates message 680 destined for end node 630 by examining the included end node identifier. To do. The access node 610 then sends a message 680 that includes at least a portion of the message 670. In accordance with the present invention, message 680 includes the CID of the physical attachment point of access node 620 that broadcasts signal 640.

  The end node 630 received the message 680 from the access node 610, but sent it earlier by checking the CID field included in the message 680, for example, by comparing it with the stored CID information. In response to message 650, it is determined that message 680 came from access node 620.

  FIG. 7 illustrates general signaling implemented in accordance with various embodiments of the invention. The signaling is illustrated in connection with the general system 100 shown in FIG. End node 710 is a simplified representation of end node 200 of FIG. 2 and is the same or similar to end nodes 144, 146, 144 ′, 146 ′, 144 ″, 146 ″ of system 100 of FIG. . Access nodes 740, 750 are similar to access nodes 140, 140 ′, 140 ″ of the system of FIG. 1, which are implemented using access node 300 of FIG. The end node 710 includes a message generation module 720 and a link selection module 730. The message generation module 720 of Fig. 7 is used by an application running on the end node 710 to generate a message for that purpose. For example, a connection control protocol application may be included and active in end node 710. This allows end node 710 to have one or both of access nodes 740, 750. And the end node 710 Communicating with the access node for purposes of creating, disconnecting, and / or modifying the queue, another example is a quality of service (QoS) application that may be included in the end node 710. QoS application Can change the QoS characteristics of various links of the end node 710. If present, the link selection module 730 of Fig. 7 performs link latency requirements, link channel condition requirements, link error rate requirements, and Measure various indicators for connection quality, including link transmit power requirements, e.g. on a per-message basis, or at a particular point in time, which of the available links is most likely to be transmitted for the next message. Determine if it is suitable.

  The resulting link quality information can be used in various embodiments to determine which of many simultaneous links a message should be sent at a particular time.

  In FIG. 7, the end node 710 maintains a bi-directional link with the access nodes 740, 750, which means that it can send and receive messages with the access nodes 740, 750. In this embodiment of the invention, the message generation module 720 of the end node 710 generates a message 759 with a final destination access node 740. Message 759 is first sent into link selection module 730 of end node 710. The link selection module 730 selects a link with the access node 740, 750 to which the next message is transmitted. This link determination function is based on link characteristics including at least one of link latency requirements, link condition requirements, link error rate requirements, and link transmission power requirements.

  In the general embodiment of the invention as shown in FIG. 7, the link selection module 730 selects a link to the access node 740 and sends a message 760 over this link. Message 760 includes some portion of message 759, which in some embodiments of the invention is used to send a message over a link between end node 710 and access node 740. Contains additional fields to be played. For example, this additional field is a link frame field in some embodiments. Since the final destination of messages 759, 760 is access node 740, access node 740 receives message 760, processes the received message, and sends message 765 to end node 710, for example. To respond by. Message 765 is received by end node 710 and delivered to message generation module as message 766. Message generation module 720 generates a second message 769 with access node 740 as the final destination. Message 769 is sent to a link selection module 730 that selects the link over which message 769 is transmitted. In this embodiment of the invention, a link to access node 750 is selected and message 770 is sent to access node 750. Message 770 includes at least a portion of message 769, and in some embodiments of the invention is used for sending a message over a link between end node 710 and end node 750. Contains additional fields. For example, this additional field is a link frame field in some embodiments.

  In one embodiment of the invention, link selection module 730 adds an identifier of access node 740, such as, for example, a physical attachment point identifier, along with at least a portion of message 769 when constructing message 770. This is because the link selected by link selection module 730 for transmission of message 770 does not match the final destination of message 770, which is access node 740. In another embodiment of the invention, prior to sending messages 760, 770 independent of the links selected for these transmissions, the link selection module may identify the final destination identifier of messages 760, 770. Add In a further embodiment of the invention, messages 759 and 769 include their final destination identifier. For example, in the exemplary embodiment example of FIG. 7, the final destination identifier matches the access node 740.

  In one general embodiment of the invention, message 770 is implemented in accordance with message 500 of FIG. 5 where CID field 520 identifies access node 740. Access node 750 receives and processes message 770. For example, by examining the final destination of the message, such as the physical attachment point identifier in the CID field 520 of the message 500 of FIG. 5, the access node 750 determines that the message 770 is not itself (eg, Determine that it is directed to another node identified by the final destination identifier (such as the CID in the CID field). The access node 750 finds a network address (eg, an IP address) corresponding to the PID included in the message 770, in order to find its address resolution table (address resolution in the access node 300 in FIG. 3). The physical connection point identifier (PID) included in the message 770 in the solution table 311) is checked.

  Access node 750 encapsulates at least a portion of message 770 within an appropriate network layer header and sends message 775 to access node 740. Message 775 includes at least a portion of message 770 and at least some of the IP addresses of access node 740. Further, the message 775 may, in some embodiments, include the IP address of the access node 750, the PID of the access node 740 included in the message 770, the PID of the access node 750 from which the message 770 was received, the end node 710 identifiers and some or all of the session identifiers for encapsulation (also referred to as tunneling) of messages between access node 750 and access node 740 may be included. The access node 740 receives the message 775 and recognizes from the destination PID included in the message 775 that it is a message directed to itself.

  In one embodiment of the invention, the access node 740 responds by sending a message 780 that includes at least a portion of the message 775. Access node 750 receives message 780 including end node 710 and sends message 785 to end node 710. Message 785 includes at least a portion of message 780. End node 710 receives message 785 and forwards message 786 to message generation module 720.

  In other embodiments of the present invention, the access node 740 responds by sending a message 780 ′ including at least a portion of the message 775 to the end node 710. Message 780 'is sent over a direct link between access node 740 and end node 710.

  FIG. 8 illustrates the general signaling performed in accordance with the general embodiment of the present invention, where the end node is used as part of the neighbor discovery and CID routing information update process. Signaling is illustrated in connection with a typical system, such as system 100 shown in FIG. End node 810 is a simplified view of end node 200 of FIG. 2 and is the same or similar to end nodes 144, 146, 144 ′, 146 ′, 144 ″, 146 ″ of system 100 of FIG. is doing. Access nodes 840, 850 are the same as or similar to access nodes 140, 140 ′, 140 ″ of system 100 of FIG. 1, and are implemented using, for example, an access node of the type illustrated in FIG. In FIG. 8, the example end node 810 has a bi-directional communication link with the access node 840, which allows messages to be sent to and received from the access node 840.

  In FIG. 8, end node 810 generates message 860 and sends it to access node 840. Message 860 includes an identifier that identifies access node 850 as the destination for this message. The access node 840 receives the message 860 and enters the network address by searching an address resolution table, such as the address resolution table 311 of the access node 300 of FIG. Attempts to determine the access node 850 identifier included in the message. In the example of FIG. 8, the access node 840 fails to determine the identifier. Access node 840 then sends message 865 to end node 810. Message 865 includes an indication that the message could not be routed due to a decision failure.

  In one embodiment of the invention, at this point, end node 810 exchanges various messages, shown as two-way arrow message 870 in FIG. Establish a link. However, if a bi-directional link already exists with the access node 850, this is not necessary. In another example in which the present invention is used, end node 810 already has a bi-directional link with access node 850 in addition to a bi-directional link with access node 840.

  By using a bidirectional link with access node 850, end node 810 sends a new neighbor advertisement message 875 to access node 850. Message 875 includes at least the identifier of access node 840 and the network layer address of access node 840. Thus, the access node 850 addresses and stores an identifier, such as the PID of the access node 840, for example, and the network layer identifier, for example, for future determination of the physical layer by the access node 850. Both a corresponding link layer address, such as a MAC address that can be provided. In one embodiment of the present invention, the access node 840 identifier is a physical attachment point identifier, and in another embodiment of the present invention is a link layer identifier. The network layer identifier of the access node 840 is known to the end node 810 from the communication message 897 communicated to the end node 810 during or after establishment of the link with the access node 840.

  In an alternative embodiment of the present invention, end node 810 sends message 875 'instead of message 875. Message 875 ′ has the same or similar message content as message 875, but instead of being sent directly to access node 850, it is sent to access node 850 via access node 840. Access node 840 then routes message 875 'to access node 850 as message 875 ". Unlike message 860, message 875' is a network address that contains the access node 850 network address as its destination. Note that the network address of the access node 850 is derived from the communication message 899 communicated during or after the establishment of the link with the access node 850 from the end node 810. For this reason, the access node 840 does not need to perform CID for address resolution operations, but uses the network address of the access node 850, such as an IP address, It is possible to route the message 875 "and to the access node 850.

  Access node 850 receives message 875 and sends a new neighbor generation message 880 to the network address of access node 840 retrieved from message 875. Message 880 includes a connection identifier to the network layer address mapping for access node 850. In other embodiments of the present invention, message 880 includes a link layer identifier to network layer address mapping for access node 850. In another embodiment of the present invention, message 880 includes, but is not limited to, a tunnel address identifier and a tunnel session identifier for packet forwarding between access nodes 840 and 850, and supported applications. , Including additional neighbor information used for accommodating end node handoffs, including access node 850 capabilities regarding protocol, load, and quality of service. Access node 840 receives message 880 and stores the information contained in message 880 in memory for future use in the CID, eg, for network address resolution operations. Access node 840 responds with message 882 that acknowledges receipt of the information contained in message 880.

  In an embodiment of the present invention, access node 840 includes in message 882 a connection identifier for network layer address mapping of access node 850 and a link for network layer address mapping of access node 850. A layer identifier and, but not limited to, a tunnel address identifier and a tunnel session identifier for packet transfer between access nodes 840 and 850, and / or supported applications, protocols, loads, And neighbor information used for accommodating end node handoffs, including information indicating access node 840 capabilities regarding quality of service. The access node 840 receives the message 880 and stores the information contained in the message 880 in memory for future use in routing the message, for example. In certain embodiments of the invention, messages 883, 884 are not used.

  In another embodiment of the present invention, access node 840 message 882 includes an acknowledgment of receipt of the information contained in message 880. In this embodiment of the invention, the access node 840 includes a connection identifier for the network layer address mapping of the access node 850, a link layer identifier for the network layer address mapping of the access node 850, and Without limitation, the access node's 840, 850, 850's tunnel address identifier and tunnel session identifier for forwarding packets, supported applications, protocols, loads, and quality of service of the access node 840 A message 883 is sent that includes at least some of the neighbor information used to accommodate the end node handoff that includes the function. Access node 850 receives message 883 and stores the information contained in message 883 in memory, eg, for future use. The access node 850 responds with a message 884 that acknowledges receipt of this information.

  After the exchange of identifiers and neighbor information for address mapping between access nodes 840, 850 via messages 880, 882 and optionally 883, 884, end node 810 sends message 890 to access node 840. send.

Similar to message 890, in one embodiment of the invention, message 890 is also the same as or similar to message 500 of FIG. Message 890 identifies its final destination as access node 850. The access node 840 receives the message 890, searches the memory for a mapping between the access node 850's network address and the access node 850 identifier, and the address resource already occupied by the message 880. Find its network address in the solution table. Access node 840 encapsulates message 890 according to the information in the resolution table and sends it to access node 850 in the form of message 891. Access node 850 again responds with message 891 and message 892 using information in the address resolution table. The access node 840 sends a message 893 including at least a part of the message 892 received from the access node 850 to the end node 810, and the end node 810 and the access node 850 via the access node 840 Complete communication exchange between.

  In the manner as described above, by using messages from end node 810, access nodes 840, 850 are provided with address and / or PID information about each other that can be used to route received messages. . Thus, when access nodes are added to the network, end nodes can discover their presence from the broadcast signal and notify the new neighbors of the access node. As part of this notification process, after this notification process is complete, sufficient address information is delivered to facilitate the routing of network PID-based messages.

  In various embodiments, the nodes described herein perform steps corresponding to one or more methods of the present invention, such as, for example, signal processing steps, message generation steps, and / or transmission steps. Therefore, it is realized by using one or a plurality of modules. Thus, in some embodiments, the various functions of the present invention are implemented using modules. Such modules can be implemented using software, hardware, or a combination of software and hardware. Many of the methods or method steps described above are implemented using machine-executable instructions such as software contained within a machine-readable medium such as a memory device such as RAM, floppy disk, etc. For example, a machine such as a general purpose computer with or without additional hardware is controlled to implement all or part of the methods described above, such as one or more nodes. Accordingly, the present invention relates to a machine-readable medium containing machine-executable instructions for causing a machine, such as a processor or associated hardware, to perform one or more of the steps described above.

  Many further variations on the methods and apparatus of the present invention described above will become apparent to those skilled in the art in view of the above description of the invention. Such variations are considered to be within the scope of the present invention. The method and apparatus of the present invention, in various embodiments, may be CDMA, orthogonal frequency division multiplexing (OFDM), or various others used to provide a wireless communication link between an access node and a mobile node. Any type of communication technology can be used. In some embodiments, the access node is implemented as a base station that establishes a communication link with the mobile node using OFDM and / or CDMA. In various embodiments, the mobile node may be a notebook computer, personal digital assistant, or other portable device including receiver / transmitter circuitry and logic and / or routines to implement the method of the present invention. Implemented as a device.

Claims (20)

A method of operating a wireless terminal having a first communication link having a first access node and a second communication link having a second access node, the first link comprising: At the first physical connection point identified by the physical connection point identifier of the second access point, the second link terminating at the first access node and the second link identified by the second physical connection point identifier. Terminating at the second access node at a physical connection point of:
Generating a message including a physical connection point identifier that is one of the first and second physical connection point identifiers;
Selecting one of the first communication link and the second communication link to be used for communication of the message.   The method of claim 1, further comprising transmitting the message over a selected one of the first communication link and the second communication link.   The selecting may be based on at least one of a link latency requirement, a link channel condition requirement, a link error rate requirement, and a link transmission power requirement, based on the first communication link and the second communication link. 3. The method of claim 2, comprising selecting one of.   4. The one of the first and second communication links that is not terminated at a physical connection point identified by the physical connection point identifier included in the message is selected to communicate the message. the method of.   The method of claim 2, wherein the physical connection point identifier comprises a cell identifier.   The method of claim 5, wherein the physical attachment point identifier further comprises a carrier identifier.   The method of claim 6, wherein the physical attachment point identifier further comprises a sector identifier.   6. The method of claim 4, further comprising determining the first physical attachment point identifier from a number of broadcast signals transmitted by the first access node.   9. The method of claim 8, further comprising determining the second physical attachment point identifier from a number of broadcast signals transmitted by the second access node. The first access node and the second access node are base stations;
The method of claim 9, wherein transmitting the message includes transmitting an OFDM signal. A wireless terminal having a first communication link having a first access node and a second communication link having a second access node, wherein the first link is a first physical connection point At a first physical connection point identified by an identifier, terminating at the first access node, the second link is a second physical connection point identified by a second physical connection point identifier The wireless terminal is terminated at the second access node,
A message generation module for generating a message including a physical connection point identifier that is one of the first and second physical connection point identifiers;
A wireless terminal comprising a link selection module for selecting one of the first communication link and the second communication link to be used for communication of the message.   The wireless terminal of claim 11, further comprising a transmitter module that transmits the message over a selected one of the first communication link and the second communication link.   The link selection module is configured to determine the first communication link and the second communication link based on at least one of a link latency requirement, a link channel condition requirement, a link error rate requirement, and a link transmission power requirement. The wireless terminal according to claim 12, wherein one of the two is selected.   14. The one of the first and second communication links that is not terminated at a physical connection point identified by the physical connection point identifier included in the message is selected to communicate the message. Wireless terminal.   The wireless terminal stores the first physical connection point identifier and the second physical connection point identifier in a memory, and each of the first physical connection point identifier and the second physical connection point identifier is a cell. The wireless terminal according to claim 12, comprising an identifier.   The wireless terminal according to claim 15, wherein the stored first and second physical connection point identifiers each further include a carrier identifier.     The wireless terminal of claim 16, wherein the stored first and second physical attachment point identifiers each further comprise a sector identifier.   15. The wireless terminal of claim 14, further comprising a physical connection point identifier determination module that determines the first physical connection point identifier from a number of broadcast signals transmitted by the first access node.   The wireless terminal according to claim 18, wherein the physical connection point determination module also determines the second physical connection point identifier from a number of broadcast signals transmitted by the second access node.   The wireless terminal according to claim 18, wherein the first access node and the second access node are base stations, and the transmitter module includes an OFDM transmitter.

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